4-amido-2-aryl-1,2,4-triazolo[4,3-a]quinoxalin-1-ones as new potent and selective human A3 adenosine receptor antagonists. synthesis, pharmacological evaluation, and ligand-receptor modeling studies.

A structural investigation on some 4-amido-2-phenyl-1,2-dihydro-1,2,4-triazolo[4,3-a]quinoxalin-1-one derivatives, designed as human A3 adenosine receptor (hA3 AR) antagonists, is described. In the new derivatives, some acyl residues with different steric bulk were introduced on the 4-amino group, and their combination with the 4-methoxy group on the 2-phenyl moiety, and/or the 6-nitro/6-amino substituent on the fused benzo ring, was also evaluated. Most of the new derivatives were potent and selective hA3 AR antagonists. SAR analysis showed that hindering and lipophilic acyl moieties not only are well tolerated but even ameliorate the hA3 affinity. Interestingly, the 4-methoxy substituent on the appended 2-phenyl moiety, as well as the 6-amino group, always exerted a positive effect, shifting the affinity toward the hA3 receptor subtype. In contrast, the 6-nitro substituent exerted a variable effect. An intensive molecular modeling investigation was performed to rationalize the experimental SAR findings.

Scaffold identification of a new class of potent and selective BCRP inhibitors.

We recently reported the synthesis and quantitative structure-activity relationships of a new breast cancer resistance protein (BCRP) inhibitor class. In the study presented herein, we investigated the possibility to better define the scaffold of this compound class by removing or modifying the aromatic ring A with various substituents selected on the basis of their electronic and lipophilic properties. The results show that this aromatic ring is important, but not essential, for activity. Many of the selected substituents led to compounds with low activity, but in some cases activity was retained. Among these, a phenolic hydroxy group proved to impart as much potency to the molecule as a hydroxyethyl side chain, initially considered necessary for activity. This derivative is one of the most active compounds in this class, maintaining an inhibitory activity similar to that of the reference compound; it is also selective for BCRP.

Synthesis and quantitative structure-activity relationships of selective BCRP inhibitors.

The breast cancer resistance protein (BCRP/ABCG2) is a member of the ABC transporter superfamily. This protein has a number of physiological functions, including protection of the human body from xenobiotics. The overexpression of BCRP in certain tumor cell lines causes cross-resistance against various drugs used in chemotherapeutic treatment. In a previous work we showed that a new class of compounds derived from XR9576 (tariquidar) selectively inhibits BCRP. In this work we synthesized more members of this class, with modification on the second and third aromatic rings. The inhibitory activities against BCRP and P-gp were assayed using a Hoechst 33342 assay for BCRP and a calcein AM assay for P-gp. Finally, quantitative structure-activity relationships for both aromatic rings were established. The results obtained show the importance of the electron density on the third aromatic ring, influenced by substituents, pointing to interactions with aromatic residues of the protein binding site. In the second aromatic ring the activity of compounds is influenced by the steric volume of the substituents.

Interactions of the multidrug resistance modulators tariquidar and elacridar and their analogues with P-glycoprotein.

Tariquidar and elacridar are among the most potent inhibitors of the multidrug resistance transporter P-glycoprotein (P-gp), but how they interact with the protein is yet unknown. In this work, we describe a possible way in which these inhibitors interact with P-gp. We rely on structure-activity relationship analysis of a small group of tariquidar and elacridar analogues that was purposefully selected, designed, and tested. Structural modifications of the compounds relate to the presence or absence of functional groups in the tariquidar and elacridar scaffolds. The activity of the compounds was evaluated by their effects on the accumulation of P-gp substrates rhodamine 123 and Hoechst 33342 in resistant tumor cells. The data allow estimation of the ability of the compounds to interact with the experimentally proposed R- and H-sites to which rhodamine 123 and Hoechst 33342 bind, respectively. Using an inward-facing homology model of human P-gp based on the crystallographic structure of mouse P-gp, we demonstrate that these binding sites may overlap with the binding sites of the QZ59 ligands co-crystallized with mouse P-gp. Based on this SAR analysis, and using flexible alignment and docking, we propose possible binding modes for tariquidar and elacridar. Our results suggest the possibility for the studied compounds to bind to sites that coincide or overlap with the binding sites of rhodamine 123 and Hoechst 33342. These results contribute to further understanding of structure-function relationships of P-gp and can help in the design of selective and potent P-gp inhibitors with potential clinical use.